/*
Unix SMB/CIFS implementation.
multiple interface handling
Copyright (C) Andrew Tridgell 1992-2005
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include "includes.h"
#include "system/network.h"
#include "lib/socket/netif.h"
#include "lib/util/dlinklist.h"
/** used for network interfaces */
struct interface {
struct interface *next, *prev;
struct ipv4_addr ip;
struct ipv4_addr nmask;
const char *ip_s;
const char *bcast_s;
const char *nmask_s;
};
static struct interface *local_interfaces;
#define ALLONES ((uint32_t)0xFFFFFFFF)
/*
address construction based on a patch from fred@datalync.com
*/
#define MKBCADDR(_IP, _NM) ((_IP & _NM) | (_NM ^ ALLONES))
#define MKNETADDR(_IP, _NM) (_IP & _NM)
static struct ipv4_addr tov4(struct in_addr in)
{
struct ipv4_addr in2;
in2.addr = in.s_addr;
return in2;
}
/****************************************************************************
Try and find an interface that matches an ip. If we cannot, return NULL
**************************************************************************/
static struct interface *iface_find(struct in_addr ip, BOOL CheckMask)
{
struct interface *i;
if (is_zero_ip(tov4(ip))) return local_interfaces;
for (i=local_interfaces;i;i=i->next)
if (CheckMask) {
if (same_net(i->ip,tov4(ip),i->nmask)) return i;
} else if (i->ip.addr == ip.s_addr) return i;
return NULL;
}
/****************************************************************************
add an interface to the linked list of interfaces
****************************************************************************/
static void add_interface(struct in_addr ip, struct in_addr nmask)
{
struct interface *iface;
struct ipv4_addr bcast;
if (iface_find(ip, False)) {
DEBUG(3,("not adding duplicate interface %s\n",inet_ntoa(ip)));
return;
}
iface = talloc(local_interfaces, struct interface);
if (!iface) return;
ZERO_STRUCTPN(iface);
iface->ip = tov4(ip);
iface->nmask = tov4(nmask);
bcast.addr = MKBCADDR(iface->ip.addr, iface->nmask.addr);
/* keep string versions too, to avoid people tripping over the implied
static in sys_inet_ntoa() */
iface->ip_s = talloc_strdup(iface, sys_inet_ntoa(iface->ip));
iface->nmask_s = talloc_strdup(iface, sys_inet_ntoa(iface->nmask));
if (nmask.s_addr != ~0) {
iface->bcast_s = talloc_strdup(iface, sys_inet_ntoa(bcast));
}
DLIST_ADD_END(local_interfaces, iface, struct interface *);
DEBUG(2,("added interface ip=%s nmask=%s\n", iface->ip_s, iface->nmask_s));
}
/**
interpret a single element from a interfaces= config line
This handles the following different forms:
1) wildcard interface name
2) DNS name
3) IP/masklen
4) ip/mask
5) bcast/mask
**/
static void interpret_interface(const char *token,
struct iface_struct *probed_ifaces,
int total_probed)
{
struct in_addr ip, nmask;
char *p;
int i, added=0;
ip.s_addr = 0;
nmask.s_addr = 0;
/* first check if it is an interface name */
for (i=0;i<total_probed;i++) {
if (gen_fnmatch(token, probed_ifaces[i].name) == 0) {
add_interface(probed_ifaces[i].ip,
probed_ifaces[i].netmask);
added = 1;
}
}
if (added) return;
/* maybe it is a DNS name */
p = strchr_m(token,'/');
if (!p) {
/* don't try to do dns lookups on wildcard names */
if (strpbrk(token, "*?") != NULL) {
return;
}
ip.s_addr = interpret_addr2(token).addr;
for (i=0;i<total_probed;i++) {
if (ip.s_addr == probed_ifaces[i].ip.s_addr) {
add_interface(probed_ifaces[i].ip,
probed_ifaces[i].netmask);
return;
}
}
DEBUG(2,("can't determine netmask for %s\n", token));
return;
}
/* parse it into an IP address/netmasklength pair */
*p++ = 0;
ip.s_addr = interpret_addr2(token).addr;
if (strlen(p) > 2) {
nmask.s_addr = interpret_addr2(p).addr;
} else {
nmask.s_addr = htonl(((ALLONES >> atoi(p)) ^ ALLONES));
}
/* maybe the first component was a broadcast address */
if (ip.s_addr == MKBCADDR(ip.s_addr, nmask.s_addr) ||
ip.s_addr == MKNETADDR(ip.s_addr, nmask.s_addr)) {
for (i=0;i<total_probed;i++) {
if (same_net(tov4(ip), tov4(probed_ifaces[i].ip), tov4(nmask))) {
add_interface(probed_ifaces[i].ip, nmask);
return;
}
}
DEBUG(2,("Can't determine ip for broadcast address %s\n", token));
return;
}
add_interface(ip, nmask);
}
/**
load the list of network interfaces
**/
static void load_interfaces(void)
{
const char **ptr;
int i;
struct iface_struct ifaces[MAX_INTERFACES];
struct ipv4_addr loopback_ip;
int total_probed;
if (local_interfaces != NULL) {
return;
}
ptr = lp_interfaces();
loopback_ip = interpret_addr2("127.0.0.1");
/* probe the kernel for interfaces */
total_probed = get_interfaces(ifaces, MAX_INTERFACES);
/* if we don't have a interfaces line then use all interfaces
except loopback */
if (!ptr || !*ptr || !**ptr) {
if (total_probed <= 0) {
DEBUG(0,("ERROR: Could not determine network interfaces, you must use a interfaces config line\n"));
}
for (i=0;i<total_probed;i++) {
if (ifaces[i].ip.s_addr != loopback_ip.addr) {
add_interface(ifaces[i].ip,
ifaces[i].netmask);
}
}
}
while (ptr && *ptr) {
interpret_interface(*ptr, ifaces, total_probed);
ptr++;
}
if (!local_interfaces) {
DEBUG(0,("WARNING: no network interfaces found\n"));
}
}
/**
unload the interfaces list, so it can be reloaded when needed
*/
void unload_interfaces(void)
{
talloc_free(local_interfaces);
local_interfaces = NULL;
}
/**
how many interfaces do we have
**/
int iface_count(void)
{
int ret = 0;
struct interface *i;
load_interfaces();
for (i=local_interfaces;i;i=i->next)
ret++;
return ret;
}
/**
return IP of the Nth interface
**/
const char *iface_n_ip(int n)
{
struct interface *i;
load_interfaces();
for (i=local_interfaces;i && n;i=i->next)
n--;
if (i) {
return i->ip_s;
}
return NULL;
}
/**
return bcast of the Nth interface
**/
const char *iface_n_bcast(int n)
{
struct interface *i;
load_interfaces();
for (i=local_interfaces;i && n;i=i->next)
n--;
if (i) {
return i->bcast_s;
}
return NULL;
}
/**
return netmask of the Nth interface
**/
const char *iface_n_netmask(int n)
{
struct interface *i;
load_interfaces();
for (i=local_interfaces;i && n;i=i->next)
n--;
if (i) {
return i->nmask_s;
}
return NULL;
}
/**
return the local IP address that best matches a destination IP, or
our first interface if none match
*/
const char *iface_best_ip(const char *dest)
{
struct interface *iface;
struct in_addr ip;
load_interfaces();
ip.s_addr = interpret_addr(dest);
iface = iface_find(ip, True);
if (iface) {
return iface->ip_s;
}
return iface_n_ip(0);
}
/**
return True if an IP is one one of our local networks
*/
BOOL iface_is_local(const char *dest)
{
struct in_addr ip;
load_interfaces();
ip.s_addr = interpret_addr(dest);
if (iface_find(ip, True)) {
return True;
}
return False;
}
/**
return True if a IP matches a IP/netmask pair
*/
BOOL iface_same_net(const char *ip1, const char *ip2, const char *netmask)
{
return same_net(interpret_addr2(ip1),
interpret_addr2(ip2),
interpret_addr2(netmask));
}